The role of calcium ions during mitosis

Calcium-containing solutions were microinjected into dividing PtK1 cells to assess the effect of calcium ion concentration on the morphology and physiology of the mitotic spindle. Solutions containing 50 microM or more CaCl2 are immediately and irreversibly toxic to PtK1 cells. Those containing 5-10 microM CaCl2 cause reversible reduction in spindle birefringence followed by normal anaphase and cytokinesis. Microinjection of 5 microM or less CaCl2 into anaphase PtK1 cells has no detectable effect on the rate or extent of chromosome movement. Metaphase cells tend to enter anaphase 4-5 min after injection with 1-10 microM CaCl2, compared with an average of 16 min after injection with calcium-free buffer. Reducing the intracellular calcium concentration by injection of EGTA-CaCl2 buffers increases the lag between injection and anaphase to 20 min or more. Microinjection of calcium solutions does not promote precocious chromatid separation in nocodazole-arrested metaphase cells, indicating that the increase in calcium concentration does not induce centromere separation directly. An increase in the concentration of free calcium ions during metaphase appears to stimulate the onset of anaphase. Such an increase, regulated by the cell itself, may contribute to the initiation of chromosome separation in mammalian cells.     

Cell surface changes during mitosis and cytokinesis of epithelial cells

Summary PtK2 cells were studied with scanning electron microscopy to record changes on the cell surface during mitosis and cytokinesis. During prophase, prometaphase and metaphase, the cells remain very flat with few microvilli on their surfaces. In anaphase cells, there is a marked increase in the number of microvilli, most of which are clumped over the separating chromosomes and polar regions of the mitotic spindle leaving the surface of the interzonal spindle region relatively smooth. Microvilli appear over the interzonal spindle region in telophase and the cells also increase in height. At the beginning of cleavage, the distribution of microvilli is roughly uniform over the surface but it becomes asymmetric at the completion of cleav-age when the daughter cells begin to spread. At this time most microvilli are over the daughter nuclei and the surfaces that border the former cleavage furrow. The regions of the daughter cells distal to the furrow are the first to spread and their surfaces have very few microvilli. When chromosome movement is inhibited by either Nocodazole or Taxol, microvilli formation is inhibited on the arrested cells. Nevertheless cell rounding still takes place in the normal time period. It is concluded from these observations that the signal for the onset of chromosome movement in anaphase is accompanied by a signal for the formation of microvilli. It is suggested that there is also a separate signal for the cell-rounding event in mitosis and that microvilli do not play a role in this contractile process.     

Distribution of calcium during interphase and mitosis as observed by ion microscopy

The ion microscope, based on secondary ion mass spectrometry, has been used to demonstrate the distribution of calcium in the root tip cells of two plant species, Allium cepa and Vicia faba. Interphase nuclei showed higher intensities of calcium than cytoplasm, while nucleoli exhibited higher calcium intensities than the rest of the nucleoplasm. The chromosomes showed high intensities of calcium at all stages of mitosis. Calcium was also detected in the cell plate and phragmoplast region of dividing cells. It appears that during prophase calcium concentrates in the condensing chromosomes, and during telophase it is transferred to nucleoli. These observations suggest that chromosomes may serve as a reservoir of calcium during mitosis.     

Volume changes during mitosis in pancreatic acinar cells of the rat

The volume of interphasic and mitotic pancreatic acinar cells of 20-day-old rats was estimated by analysis of drawings from Araldite-embedded serial thick sections. Assuming the average interphase cell volume to be 100%, the volume of prophase cells was 145%, reaching a volume of 180% during anaphase. Postmitotic acinar cell volume was 74%.     

Non-centrosomal microtubules at kinetochores promote rapid chromosome biorientation during mitosis in human cells

1. Download : Download high-res image (232KB)
2. Download : Download full-size image

     

Structural changes in chromosomes driven by multiple condensin motors during mitosis

1. Download : Download high-res image (183KB)
2. Download : Download full-size image

     

Cell volume changes during rapid temperature shifts

The effect of a rapid temperature increase on the volume of different types of cells was investigated. Experiments were carried out using continuous microscopic image analysis. Volume variation of yeast cells, yeast spheroplasts and human leukaemia cells was measured during the transient phase after a thermal shift. The thermal shift was found to induce rapid increase in cell volume for cells lacking a cell wall (yeast spheroplasts and human leukaemia cells). This increase in cell volume is assumed to be a main cause of the heat shock-induced cell death. A theoretical mechanistic model that explains the behaviour of these cells is finally proposed.     

Model of mitosis based on antagonistic changes of intracellular concentration of free calcium and magnesium ions

Most of structural and metabolic events comprising mitosis can be explained by assumption of changing intracellular ratio of free Ca²⁺/free Mg²⁺ during this process. Evidence is discussed showing that the reason of changes in free divalent cations concentration during mitosis could be the shift induced by spindle protein polymerization in the $\text{SH}\text{SS}$ status of the cellular proteins affecting the membrane ion transport.     

Dynamic changes of cardiac conduction during rapid pacing

Slow conduction and unidirectional conduction block (UCB) are key mechanisms of reentry. Following abrupt changes in heart rate, dynamic changes of conduction velocity (CV) and structurally determined UCB may critically influence arrhythmogenesis. Using patterned cultures of neonatal rat ventricular myocytes grown on microelectrode arrays, we investigated the dynamics of CV in linear strands and the behavior of UCB in tissue expansions following an abrupt decrease in pacing cycle length (CL). Ionic mechanisms underlying rate-dependent conduction changes were investigated using the Pandit-Clark-Giles-Demir model. In linear strands, CV gradually decreased upon a reduction of CL from 500 ms to 230-300 ms. In contrast, at very short CLs (110-220 ms), CV first decreased before increasing again. The simulations suggested that the initial conduction slowing resulted from gradually increasing action potential duration (APD), decreasing diastolic intervals, and increasing postrepolarization refractoriness, which impaired Na(+) current (I(Na)) recovery. Only at very short CLs did APD subsequently shorten again due to increasing Na(+)/K(+) pump current secondary to intracellular Na(+) accumulation, which caused recovery of CV. Across tissue expansions, the degree of UCB gradually increased at CLs of 250-390 ms, whereas at CLs of 180-240 ms, it first increased and subsequently decreased. In the simulations, reduction of inward currents caused by increasing intracellular Na(+) and Ca(2+) concentrations contributed to UCB progression, which was reversed by increasing Na(+)/K(+) pump activity. In conclusion, CV and UCB follow intricate dynamics upon an abrupt decrease in CL that are determined by the interplay among I(Na) recovery, postrepolarization refractoriness, APD changes, ion accumulation, and Na(+)/K(+) pump function.     

Chromosome 'by-Aurora-ientation' during mitosis

New evidence from three separate laboratories, published recently in Science, has shown that centromere positioning of the CPC (chromosomal passenger complex) during early mitosis is achieved through direct interaction between the CPP (chromosomal passenger protein) survivin and histone H3. In essence, an acidic pocket in the BIR (baculovirus inhibitor of apoptosis repeat) domain of survivin binds to the NH2 tail of histone H3 specifically when it is phosphorylated at threonine 3, a mark that is placed by the mitotic kinase, haspin. These data are significant, as they describe a fundamental mechanism, conserved throughout eukaryotes, which is essential for chromosome biorientation and the maintenance of genome stability during mitosis.     

Separase regulation during mitosis

The final, irreversible step in the duplication and distribution of genomes to daughter cells takes place when chromosomes split at the metaphase-to-anaphase transition. A protease of the CD clan, separase (C50 family), is the key regulator of this transition. During metaphase, cohesion between sister chromatids is maintained by a chromosomal protein complex, cohesin. Anaphase is triggered when separase cleaves the Scc1 subunit of cohesin at two specific recognition sequences. As a result of this cleavage, the cohesin complex is destroyed, allowing the spindle to pull sister chromatids into opposite halves of the cell. Because of the final and irreversible nature of Scc1 cleavage, this reaction is tightly controlled. Several independent mechanisms impose regulation on separase activity, as well as on the susceptibility of the cleavage target Scc1 to cleavage by separase. This chapter provides an overview of these multiple levels of regulation.     

Translational control during mitosis

Translation is now recognized as an important process in the regulation of gene expression. During the cell cycle, translation is tightly regulated. Protein synthesis is necessary for entry into and progression through mitosis and conversely, modifications of translational activity are observed during the cell cycle. This review focuses on translational control during mitosis (or M-phase) and the role of CDK1/cyclin B, the universal cell cycle regulator implicated in the G2/M transition, in protein synthesis regulation.     

Chromosome condensation and decondensation during mitosis

1. Download : Download high-res image (415KB)
2. Download : Download full-size image

     

Dynamic study of cell mechanical and structural responses to rapid changes of calcium level

Cell shape control is complex since it may involve multiple cytoskeletal components and metabolic pathways. Here we present a kinetic study of the mechanical and structural responses of cells from the monocytic THP-1 line to a rapid increase of cytosolic calcium level. Cells were exposed to ionomycin in a medium of varying calcium concentration and they were probed at regular intervals for (1) cortical rigidity as determined with micropipette aspiration, and (2) content and distribution of polymerized actin, myosin or ABP-280, as determined with flow cytometry and/or confocal microscopy. An increase of free intracellular calcium level induced: (1) a biphasic deformability change with marked stiffening within a second, and significant softening a minute later; (2) a biphasic change of actin polymerization with initial decrease (within less than a second) and rapid recovery (within a few seconds); (3) a topographical redistribution of microfilaments with an oscillatory behavior of the cortical fraction, while no substantial redistribution of myosin or ABP-280 was detected. It is suggested that a regulation of cell rigidity might be achieved without any structural change by suitable modulation of the lifetime of bridges formed between microfilaments by actin binding proteins.     

The chromosome periphery during mitosis

A complex structure, visible by electron microscopy, surrounds each chromosome during mitosis. The organization of this structure is distinct from that of the chromosomes and the cytoplasm. It forms a perichromosomal layer that can be isolated together with the chromosomes. This layer covers the chromosomes except in centromeric regions. The perichromosomal layer includes nuclear and nucleolar proteins as well as ribonucleoproteins (RNPs). The list of proteins and RNAs identified includes nuclear matrix proteins (perichromin, peripherin), nucleolar proteins (perichro-monucleolin, Ki-67 antigen, B23 protein, fibrillarin, p103, p52), ribosomal proteins (S1) and snRNAs (U3 RNAs). Only limited information is available about how and when the perichromosomal layer is formed. During early prophase, the proteins extend from the nucleoli towards the periphery of the nucleus. Thin cordon-like structures reach the nuclear envelope delimiting areas in which chromosomes condense. At telophase, the proteins are associated with the part of the chromosomes remaining condensed and accumulate in newly formed nucleoli in regions where chromatin is already decondensed. The perichromosomal layer contains several different classes of proteins and RNPs and it has been attributed various roles: (1) in chromosome organization, (2) as a barrier around the chromosomes, (3) involvement in compartmentation of the cells in prophase and telophase and (4) a binding site for chromosomal passenger proteins necessary to the early process of nuclear assembly.